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Fermilab Linac Status and Outlook Briefing to the Directorate Beams Division / Proton Source Department August 9,2002. f Proton Source Department. Fermilab Linac Overview. 200 MeV proton Linac built ~ 1969-71 Began H - operation in 1977 400 MeV upgrade in 1992, original 116 MeV DTL remains
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Fermilab Linac Status and Outlook Briefing to the DirectorateBeams Division / Proton Source DepartmentAugust 9,2002
fProton Source Department Fermilab Linac Overview • 200 MeV proton Linac built ~ 1969-71 • Began H- operation in 1977 • 400 MeV upgrade in 1992, original 116 MeV DTL remains • 15 Hz hardware pulse rate, variable beam pulse rate • 45mA beam pulse current typical at 400 MeV • Variable beam pulse length, typically 10-40 microsec • Typical beam efficiency 10 MeV to 400 MeV ~ >95% • Typical 400-MeV emittance 6p mm-mr, dp/p of 0.25% • DTL accelerated ~300mA, 5usec beam pulses in 1970’s • New CCL >90mA (protons) during Jan. 1999 test Linac Briefing to Directorate August 9, 2002
fProton Source Department Linac in the Big Picture • All protons for all Fermilab physics programs currently and for the near future depend on this Linac • Proton demand for HEP is scheduled to increase 10-fold • All current program planning assumes continued operation at historical reliability, >97% availability • PreAcc and 200-MHz Linac beamline and power systems are original equipment, >30 years old • 200-MHz RF power systems in particular are based on outdated technology and at risk of obsolescence (1) • Original Linac expertise will soon be gone • Focus here is on PreAcc and 200-MHz Linac Linac Briefing to Directorate August 9, 2002
fProton Source Department Linac Operational Issues and Risks • Loss of individuals with critical knowledge and skills • Black Magic of Ion Source maintenance • PreAcc High Voltage DC expertise • Linac vacuum and major mechanical system maintenance • High Power RF Vacuum Tube expertise • 750-KeV Buncher or DTL Accelerating Cavity failure • Buncher cavity from MURA, still tuned with C-clamp • Drift-tube/quadrupole failure (up to 10 weeks recovery, esp. Tank 1) • Cavity vacuum seals, esp. drift tube stems • Obsolescence of critical high voltage & RF power tubes • Modulator switch tubes (last manufacturer, Triton, has dropped line) • 7835 type 200-MHz RF power amplifier tubes (single source) • 30-year old quadrupole power supplies containing a total of ~ 1.5 cubic yards of PCB capacitors Linac Briefing to Directorate August 9, 2002
Tank 1 • Don Young (Fermilab ID #002) on Tank 1 • “Tank 1 is a kludge, it was built as a prototype” • “It was thrown together with parts from the Village” • “It was rushed to “get a beam at NAL” ” • “There are inherent problems with tuning and drift tube alignment” • “Contributes factor of 3 emittance growth” • Contains greatest number, smallest, most closely spaced drift tubes of all Tanks (6 cm center-to-center at 750 KeV) • Drift tube alignment is a serious issue • No post-couplers to stabilize Tank tuning • Concerns are especially important today due to maintenance vulnerability exacerbated by loss of original expertise (This background picture is NOT of Tank 1)
fProton Source Department 7835 Power Amplifier Tubes • Fewer than 30 sockets in the world -- 20 of these are at FNAL, BNL, and LANL (2) • No alternative PA tube or 200-MHz power system is available • Burle Industries is the sole 7835 builder/re-builder • Linac staff visited Burle in June and returned with positive impression of their commitment, but Triton gave little warning • Average tube operating life is apparently becoming shorter • Can tubes be rebuilt only a limited number of times? • Has vendor lost the magic recipe? • Have we lost the expertise to maximize operating life? • We must build up spares inventory as hedge against vendor production problems or drop-out; this will not eliminate the vulnerability Linac Briefing to Directorate August 9, 2002
Three tubes with >30000 hours excluded In service now 9 stations 5 stations History of 7835 Tube Operating Lifetimes (2)
fProton Source Department 200-MHz Modulator Switch Tubes • Each modulator requires three F1123 switch tubes • We use about 7 tubes/year on average • Final order last year for 50 Triton tubes • 49 received to date • 38 tested good • 3 tested bad • 6 awaiting test • 2 in test • 1 yet to be received • One tube successfully rebuilt by Econco recently • No direct replacement is available Linac Briefing to Directorate August 9, 2002
fProton Source Department Views of the Future I: Only 6 years • Present Linac will serve Run II, MiniBooNE, NUMI, and SY120 until LHC turns on in 2008, then limp into oblivion • Just maintain existing equipment • Plan no major improvement programs • Rely on present stock of switch tubes • Build up minimal stock of 7835 PA tubes • Maintain present operating and maintenance staff levels Linac Briefing to Directorate August 9, 2002
fProton Source Department Views of the Future II: 10-12 Years • Present Linac will be expected to run strongly and reliably through delayed LHC turn-on and through B-TeV • Strongly push switch tube rebuild program or, failing that, begin 200-Mhz modulator redesign program • Build up substantial 7835 PA tube stock, ~5 yr supply • Replace quadrupole power supplies • Execute major improvement programs for aging conventional systems, e.g. water, vacuum • Begin highly proactive maintenance of existing systems • Augment present operating and maintenance staff to facilitate improvement programs Linac Briefing to Directorate August 9, 2002
fProton Source Department Views of the Future III: Beyond 12 Years • Fermilab expects to run hadron physics programs beyond the foreseeable future • It would seem extremely unwise to plan to rely on the existing 200-Mhz Linac for more than ~12-15 years • Planning should focus on defining beam requirements ASAP, then get on with design, approval, and construction of new machine • A goal should be to realize and take advantage of benefits of new machine at the earliest possible date (2007 is optimistic) • Continue proactive maintenance of existing systems • Maintain current operational/maintenance staffing level and establish separate “project” department to carry out new machine Linac Briefing to Directorate August 9, 2002
fProton Source Department Minimal Thinking => Domino Thinking • Replace Cockcroft-Walton PreAcc with RFQ to reduce long-term maintenance problems and vulnerability to loss of key expertise • It would be foolish to build 750-KeV RFQ to inject into a vulnerable, emittance trashing Tank 1 • It would be foolish to rebuild Tank 1 given the vulnerabilities of the 200-MHz RF power systems • Ergo: replace the whole front end up to 116 MeV with klystron driven 402-MHz Linac with RFQ Injector Linac Briefing to Directorate August 9, 2002
fProton Source Department The 402-MHz Upgrade Option • Replace Cockcroft-Walton PreAcc with a 3-MeV, 402-MHz RFQ • Preserve beam emittance with a 402-MHz, ramped gradient DTL Tank 1 • Accelerate to 70 MeV with three additional 402-MHz DTL tanks • Match into 805-MHz CCL structure at 70 MeV • Add two modules of present CCL design to reach current 116 MeV transition energy • Requires four 402-MHz klystrons to power the RFQ/DTL systems and two copies of existing 805-MHz klystron systems to power new CCL modules Linac Briefing to Directorate August 9, 2002
fProton Source Department (Ambitious) Schedule • Complete definition of goals and requirements and initiate project approval process - 3/1/03 • Begin Linac design activities and communication with potential commercial partners - 10/1/03 • Begin design of control and diagnostics systems - 6/1/04 • Obtain construction funds - 10/1/05 • Complete fabrication and delivery of commercial components - 2/1/07 • Begin 6 month for construction and installation (in conjunction with B-TeV construction) - 4/1/07 • Begin commissioning - 10/1/07 • Return to HEP operation - 11/1/07 Linac Briefing to Directorate August 9, 2002
fProton Source Department Cost and Considerations • Estimated 402-MHz Upgrade cost (3) • Accelerator systems and components -- $24.6M • Installation and commissioning -- $ 2.5M • Building modifications -- $ 0.5M • Anticipated operational costs with present Linac • 7835 power tubes (5-6/year) -- $600K/year • Other power tubes -- $30K/year • New quadrupole power supplies -- $1000K • Water system rebuild -- $300-500K • Manpower and Expertise • Need to obtain expert design assistance not available within Lab • Commercial expertise exists (ACCSYS now Hitachi) • Original Linac required 55 people during construction and commissioning Linac Briefing to Directorate August 9, 2002
fProton Source Department Advantages of 402-MHz Upgrade • Possible ~5x increase in beam brightness • Eliminates RF power vacuum tube vulnerability • Klystrons are current technology • Klystron lifetimes are 5 times longer than present tubes • Replaces all aged Linac equipment and associated maintenance problems • Leverages on existing tunnel, building and 805-MHz Linac • Much of design and hardware may be available commercially Linac Briefing to Directorate August 9, 2002
fProton Source Department Caveats • This Domino Thinking may in fact be “Backward Thinking”: Is it focused too much upon what we have, rather than what is needed for a sound physics program? • Does the 402-MHz Linac meet TBD beam requirements? • Is the radiation shielding of the present enclosure adequate for future operations? • Will the current physics program commitments support the 402-MHz Linac construction/installation schedule? • This is an all or nothing approach with one big shutdown • What is happening with Booster during this time? • A 400-MeV Linac isn’t much use without a Booster • Booster beamline components are same age as the 200-MHz Linac and have/will have suffered considerable radiation exposure Linac Briefing to Directorate August 9, 2002
fProton Source Department Relationship to 8-GeV Linac Option • 402-MHz Upgrade • 15 Hz pulse rate • ~100 usec beam pulse • 70 mA beam current • ~1.2E18 pph potential • Retains existing 805-MHz Linac • Uses existing building and infrastructure • Booster synchrotron required • Limited future upgrade path • 8-GeV Linac • 10 Hz pulse rate • 1000 usec beam pulse • 25 mA beam current • ~5.4E18 pph potential • Replaces existing 805-MHz Linac • Requires all new civil construction • No Booster synchrotron required • Avenue to superconducting RF and Linear Collider technology Linac Briefing to Directorate August 9, 2002
fProton Source Department Conclusions • Linac “problem” ought not be considered in isolation from Booster “problem”; it is a Proton Source problem relevant to the entire Laboratory community • Solutions will take considerable lead-time to implement • Six year horizon for “status quo” operation is clear, given suitable attention to maintenance and acceptance of certain vulnerabilities to failure • Twelve year horizon requires improvement projects to allow continued reliability and care, planning, and $$$ are necessary to mitigate potential “tube disaster” • Expectations of a Fermilab hadron physics program beyond 12 years suggest that beam requirements should be defined as soon as possible to avoid lapse in program • New machines may or may not benefit present day operations Linac Briefing to Directorate August 9, 2002
fProton Source Department Closing • The greatest danger of all is failure to chose and actively pursue a well-defined plan for the Proton Source • At risk is the availability of protons to serve current and future Laboratory objectives and commitments Linac Briefing to Directorate August 9, 2002
References • “Status of the Low-Energy Linac 200-MHz RF Stations”, Fermilab TM-2166, March 2002 • “Analysis of Lifetime Data for the Linac 201 MHz Power Amplifiers”, Fermilab TM-2178, July 2002 • “H- Source and Linac Improvements and Upgrade”, Appendix of Chapter 8 of Proton Driver Study II, Fermilab TM-2169, May 2002 • Trip Report to Burle Industries, Elliott McCrory, June 2002 (http://mccrory.fnal.gov/memos/BurleVisit2002.htm)